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Social Networks: New Paradigms for Modeling, Applications, Computations, and Visualization. Anna Nagurney John F. Smith Memorial Professor and Director of the Virtual Center for Supernetworks and Tina Wakolbinger Isenberg School of Management University of Massachusetts at Amherst.
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Social Networks: New Paradigms for Modeling, Applications, Computations, and Visualization Anna Nagurney John F. Smith Memorial Professor and Director of the Virtual Center for Supernetworks andTina Wakolbinger Isenberg School of Management University of Massachusetts at Amherst UMASS Amherst Student Chapter of INFORMS Operations Research / Management Science Seminar Series November 19, 2004
Support Support for this research has been provided by the National Science Foundation under Grant No.: IIS-0002647 under the Management of Knowledge Intensive Dynamic Systems (MKIDS) program. This support is gratefully acknowledged.This project involves also researchers from Carnegie Mellon University, University of Michigan, Stanford, and the University of California at Irvine.
Support This grant has provided support for students, travel, books, supplies, computers, as well as for the Supernetworks Laboratory for Computation and Visualization in the Isenberg School of Management. The support is acknowledged with gratefulness.
A Story About How Social Networks Evolve • During the Spring/Summer of 2002 Professor Nagurney held the Distinguished Chaired Fulbright/University of Innsbruck Professorship at the Institute of Economic Theory at the Business School, SOWI, at the University of Innsbruck, Austria, where Tina was studying…
Outline of Presentation • Introduction to social networks • History of social network theory • Applications • Dynamic social network theory • The framework of supernetworks • Supernetworks consisting of social networks and economic networks
Definition of Social Networks • “A social network is a set of actors that may have relationships with one another. Networks can have few or many actors (nodes), and one or more kinds of relations (edges) between pairs of actors.” (Hannemann, 2001)
History (based on Freeman, 2000) • 17th century: Spinoza developed first model • 1937: J.L. Moreno introduced sociometry; he also invented the sociogram • 1948: A. Bavelas founded the group networks laboratory at MIT; he also specified centrality
History (based on Freeman, 2000) • 1949: A. Rapaport developed a probability based model of information flow • 50s and 60s: Distinct research by individual researchers • 70s: Field of social network analysis emerged. • New features in graph theory – more general structural models • Better computer power – analysis of complex relational data sets
Representation of Social Networks • Matrices • Graphs Ann Sue Nick Rob
Graphs - Sociograms (based on Hanneman, 2001) • Labeled circles represent actors • Line segments represent ties • Graph may represent one or more types of relations • Each tie can be directed or show co-occurrence • Arrows represent directed ties
Graphs – Sociograms (based on Hanneman, 2001) • Strength of ties: • Nominal • Signed • Ordinal • Valued
Visualization Software: Krackplot Sources: http://www.andrew.cmu.edu/user/krack/krackplot/mitch-circle.html http://www.andrew.cmu.edu/user/krack/krackplot/mitch-anneal.html
Connections (based on Hanneman, 2001) • Size • Number of nodes • Density • Number of ties that are present the amount of ties that could be present • Out-degree • Sum of connections from an actor to others • In-degree • Sum of connections to an actor
Distance (based on Hanneman, 2001) • Walk • A sequence of actors and relations that begins and ends with actors • Geodesic distance • The number of relations in the shortest possible walk from one actor to another • Maximum flow • The amount of different actors in the neighborhood of a source that lead to pathways to a target
Some Measures of Power (based on Hanneman, 2001) • Degree • Sum of connections from or to an actor • Closeness centrality • Distance of one actor to all others in the network • Betweenness centrality • Number that represents how frequently an actor is between other actors’ geodesic paths
Cliques and Social Roles (based on Hanneman, 2001) • Cliques • Sub-set of actors • More closely tied to each other than to actors who are not part of the sub-set • Social roles • Defined by regularities in the patterns of relations among actors
Examples of Applications (based on Freeman, 2000) • Visualizing networks • Studying differences of cultures and how they can be changed • Intra- and interorganizational studies • Spread of illness, especially HIV
Commercial Application Source: http://www.orgnet.com/sna.html
Dynamic Networks (based on Carley, 2003) • Limitations to traditional social network analysis • Focused on small bounded networks • With 2-3 types of links among one type of nodes • At one point of time • Close to perfect information
Dynamic Networks (based on Carley, 2003) • Dynamic networks • Meta matrix • Treating ties as probabilistic • Combining social networks with cognitive science and multi-agent systems • Networks and agents co-evolve
Applications of Dynamic Network Analysis (DNA) (based on Carley, 2003) • The possible effects of biological attacks on cities (BioWar, Carley et al, 2002) • Evaluation of information security within organizations (ThreatFinder, Carley, 2001) • Evaluation of how to build stable adaptive networks with high performance and how to destabilize networks (DyNet, Carley et al, 2002)
Dynet Source: http://www.casos.cs.cmu.edu/projects/DyNet/dynet_info.html
Roles of Social Networks in Economic Transactions • Examples from Sociology • Embeddedness theory • Granovetter (1985) • Uzzi (1996) • Examples from Economics • Williamson (1983) • Joskow (1988) • Crawford (1990) • Vickers and Waterson (1991) • Muthoo (1998)
Roles of Social Networks in Economic Transactions • Examples from Marketing • Relationship marketing • Ganesan (1994) • Bagozzi (1995)
Novelty of Our Research • Supernetworks show the dynamic co-evolution of economic (product, price and even informational) flows and the social network structure • Economic flows and social network structure are interrelated • Network of relations has a measurable economic value
A Multidisciplinary Approach Computer Science Engineering Supernetworks Management Science Economics and Finance
Tools That We Have Been Using • Network theory • Optimization theory • Game theory • Variational inequality theory • Projected dynamical systems theory (which we have been instrumental in developing) • Network visualization tools
Applications of Supernetworks • Telecommuting/Commuting Decision-Making • Teleshopping/Shopping Decision-Making • Supply Chain Networks with Electronic Commerce • Financial Networks with Electronic Transactions • Reverse Supply Chains with E-Cycling • Energy Networks/Power Grids • Knowledge Networks
Supernetworks Integrating Social Networks with Other Networks • We have formulated and analyzed supernetworks consisting of: • Supply chain and social networks • Financial and social networks • International supply chain and social networks • International financial and social networks
Supernetworks Integrating Social Networks with Other Networks • Decision-makers in the network can decide about the relationship levels [0,1] that they want to establish. • Establishing relationship levels incurs some costs. • Higher relationship levels • Reduce transaction costs • Reduce risk • Have some additional value (“relationship value”)
Supernetworks Integrating Social Networks with Other Networks Dynamic evolution of • Product transactions/financial flows and associated prices on the supply chain network/financial network with intermediation • Relationship levels on the social network
Supernetwork Structure: Integrated Supply Chain/Social Network System
Multicriteria Decision-Makers • Manufacturers and Retailers try to • Maximize profit • Minimize risk • Maximize relationship value • Individual weights assigned to the different criteria
Supernetwork Structure: Integrated Financial/Social Network System
Supernetwork Structure: Integrated Global Supply Chain/Social Network System
Supernetwork Structure: Integrated Global Financial/Social Network System
Types of Simulations • We can simulate • Changes in production, transaction, handling, and relationship production cost functions • Changes in demand and risk functions • Changes in weights for relationship value and risk • Addition and removal of actors • Addition and removal of multiple transaction modes • Addition and removal of countries and currencies
Summary • We model the behavior of the decision-makers, their interactions, and the dynamic evolution of the associated variables. • We study the problems qualitatively as well as computationally. • We develop algorithms, implement them, and establish conditions for convergence. • We have studied to-date "good behavior." Fascinating questions arise when there may be situations of instability, multiple equilibria, chaos, cycles, etc.
References • Bagozzi, R. P. (1995). “Reflections on Relationship Marketing in Consumer Markets,” Journal of the Academy of Marketing Science 23, 272-277. • Carley K.M. (2003)."Dynamic Network Analysis," in Dynamic Social Network Modeling and Analysis: Workshop Summary and Papers, Ronald Breiger, Kathleen Carley, and Philippa Pattison, (Eds.) Committee on Human Factors, National Research Council, National Research Council. 133-145. • Crawford, V. P. (1990). “Relationship-Specific Investment,” The Quarterly Journal of Economics 105, 561-574. • Cruz, J. M., Nagurney, A., and Wakolbinger. T. (2004), “Financial Engineering of the Integration of Global Supply Chain Networks and Social Networks with Risk Management,” see: http://supernet.som.umass.edu • Freeman L.C. (2000) "Social Network Analysis: Definition and History", In A. E. Kazdan, ed. Encyclopedia of Psychology. New York: Oxford University Press, Vol. 6, 350-351. • Ganesan, S. (1994). “Determinants of Long-Term Orientation in Buyer-Seller Relationships,” Journal of Marketing 58, 1-19.
References • Granovetter, M. (1985). “Economic Action and Social Structure: The Problem of Embeddedness,”American Journal of Sociology 91, 481-510. • Hannemann R.A. (2001) “Introduction to Social Network Methods”http://faculty.ucr.edu/%7Ehanneman/SOC157/TEXT/TextIndex.html • Joskow, P. L. (1988). “Asset Specificity and the Structure of Vertical Relationships: Empirical Evidence,” Journal of Law, Economics, and Organization 4, 95-117. • Muthoo, A. (1998). “Sunk Costs and the Inefficiency of Relationship-Specific Investment,”Economica 65, 97-106. • Nagurney. A., Wakolbinger, T., and Zhao, L. (2004), “The Evolution and Emergence of Integrated Social and Financial Networks with Electronic Transactions: A Dynamic Supernetwork Theory for the Modeling, Analysis,and Computation of Financial Flows and Relationship Levels,” see: http://supernet.som.umass.edu
References • Nagurney, A., Cruz, J., and Wakolbinger, T. (2004), “The Co-Evolution and Emergence of Integrated International Financial Networks and Social Networks: Theory, Analysis, and Computations,” to appear in a Springer volume on Globalization and Regional Economic Modeling • Uzzi, B. (1998). “Embeddedness in the Making of Financial Capital: How Social Relations and Networks Benefit Firms Seeking Financing,” American Sociological Review 64, 481-505. • Vickers, J. and M. Waterson. (1991). “Vertical Relationships: An Introduction,” The Journal of Industrial Economics 39, 445-450. • Wakolbinger, T., and Nagurney, A. (2004), “Dynamic Supernetworks for the Integration of Social Networks and Supply Chains with Electronic Commerce: Modeling and Analysis of Buyer-Seller Relationships with Computations,” to appear in Netnomics • Williamson, O. E. (1983). “Credible Commitments: Using Hostages to Support Exchange,” The American Economic Review 73, 519-540.
Virtual Center for Supernetworks The full text of the papers can be found under Downloadable Articles at: http://supernet.som.umass.edu
Thank you! The Virtual Center for Supernetworks